A passenger cable transportation system, the cable system comprising: at least one cabin for transporting passengers; at least one station for passengers boarding and landing from the cabin; two lateral guides facing each other and configured to guide the cabin into the station along an advancing direction, wherein there is a clearance between the lateral guides and the cabin; and at least one blocking device configured to block the cabin in relation to the lateral guides at least along a direction transversal to the advancing direction level with at least one part of the station.

The invention described refers to an equipment and corresponding method that enables side sliding load transfer between one vehicle/structure acting as loader, and another vehicle/structure acting as receptor. Both loaders and receptors can be vehicles or piers using a side sliding loading system that includes lifting and lateral displacement equipment. The great innovation of this system is the appearing of carriages consisting of 2 chassis, one inferior and one superior, both mobile and independent, that are coupled to form a single carriage. One of the equipment developed, automatically auto-load/unload standard containers to/from railway wagons and fixed platforms. This equipment can be loaded directly by the pier crane and move autonomously to the loading areas of railway wagons, trucks or buffer areas, where the containers are organized on leaving the port. When groups of these vehicles lined up parallel to the railway track, loaded on one side and empty on the other, they can load and unload the train quickly and simultaneously.

The invention described refers to an equipment and corresponding method that enables side sliding load transfer between one vehicle/structure acting as loader, and another vehicle/structure acting as receptor. Both loaders and receptors can be vehicles or piers using a side sliding loading system that includes lifting and lateral displacement equipment. The great innovation of this system is the appearing of carriages consisting of 2 chassis, one inferior and one superior, both mobile and independent, that are coupled to form a single carriage. One of the equipment developed, automatically auto-load/unload standard containers to/from railway wagons and fixed platforms. This equipment can be loaded directly by the pier crane and move autonomously to the loading areas of railway wagons, trucks or buffer areas, where the containers are organized on leaving the port. When groups of these vehicles lined up parallel to the railway track, loaded on one side and empty on the other, they can load and unload the train quickly and simultaneously.

An embodiment of the present disclosure provides a route resource controlling method, intelligent vehicle on-board controller and object controller. The method comprises: determining a route search extension distance of a train based on current location and speed of the train, wherein the current route search extension distance is the farthest distance in front of the train that is currently expected to be safe for operation based on current speed of the train; determining the currently required link and route resource contained thereof; determining the target authority of the route resource.

An embodiment of the present disclosure provides a route resource controlling method, intelligent vehicle on-board controller and object controller. The method comprises: determining a route search extension distance of a train based on current location and speed of the train, wherein the current route search extension distance is the farthest distance in front of the train that is currently expected to be safe for operation based on current speed of the train; determining the currently required link and route resource contained thereof; determining the target authority of the route resource.

A roadway conduit system includes a roadway conduit section that includes a floor portion with roadway surface configured to receive traveling vehicles, a ceiling portion, and at least one sidewall portion coupled to the floor portion and the ceiling portion such that the floor, ceiling, and at least one sidewall portions define a roadway conduit volume through which the traveling vehicles traverse the roadway conduit section. The roadway conduit section includes at least two fixedly connected preformed segments. The roadway conduit system also includes a roadway conduit ingress coupled to a first location of the roadway conduit section; a roadway conduit egress coupled to a second location of the roadway conduit section; and at least one air mover configured to circulate an airflow in the roadway conduit volume in a direction of at least one of the traveling vehicles.

A roadway conduit system includes a roadway conduit section that includes a floor portion with roadway surface configured to receive traveling vehicles, a ceiling portion, and at least one sidewall portion coupled to the floor portion and the ceiling portion such that the floor, ceiling, and at least one sidewall portions define a roadway conduit volume through which the traveling vehicles traverse the roadway conduit section. The roadway conduit section includes at least two fixedly connected preformed segments. The roadway conduit system also includes a roadway conduit ingress coupled to a first location of the roadway conduit section; a roadway conduit egress coupled to a second location of the roadway conduit section; and at least one air mover configured to circulate an airflow in the roadway conduit volume in a direction of at least one of the traveling vehicles.

A cable car system has vehicles which are coupled to a conveying cable between stations. The vehicles are decoupled from the conveying cable in the stations and are moved through the stations along guide rails. The vehicles are formed with current collectors and the stations have associated power rails. In at least one of the vehicles there is located a circuit with at least one electrical load which is supplied with electrical energy via the current collector and the power rails. At least one second circuit with at least one further electrical load is located in at least one vehicle. The second circuit is supplied with electrical energy via a single further current collector and a power rail assigned thereto. The two circuits are connected to a common current collector to which a single power rail is assigned.

A device for transporting freight articles in a ground or rail haul operations comprises a hollow housing including four corner sections, side walls, two center sections defining four openings each disposed between one edge of a center section and an edge of a respective corner section, a bottom portion and a top portion, wherein the two center portions are manufactured from see through or clear material. A door is mounted to selectively open and close a respective opening and swinging outwardly and towards a respective corner portion to selectively open the respective opening. Two channels are provided in the bottom portion, each in open communication with opposite sides of the bottom portion. Four feet or wheels are mounted on the bottom portion. Four receptacles are provided in the top portion, each sized and shaped to receive a foot therewithin.

The present disclosure relates to an autonomous rail transport system with the aid of a rail network. The rail transport system according to the disclosure comprises at least one autonomous goods-carrying rail vehicle and at least two autonomous goods terminals. The goods-carrying rail vehicle is designed to transport at least one item of goods while the goods terminals are each designed to receive and/or release at least one item of goods. The item of goods is transported autonomously from a first goods terminal to a second goods terminal with the aid of the goods-carrying rail vehicle on the rail network. The rail network of the rail transport system according to the disclosure is a streetcar-line network.